Nutrient, biotechnology, and long-term spaceflight
Long-term space explorations are fascinating topics for writing, and they are giving endless material for philosophers, engineers, and people, who are just enjoying imagine those kinds of things, what might revolutionize our point of view things in someday. The nutrient is the most important thing in manned space explorations, and that is a vital role in the manned space projects, and the idea is to grow vegetables in the spacecraft.
This kind of ideas where the nutrient can grow in the spacecraft or space station would make the space stations cheaper to maintain. The problem is that the space stations could be used in microgravity tests, and the thing is that if we would try to create artificial gravity in the space stations, what are looking like ISS (International Space Station) might break the structure, and also deny to use microgravity.
But the problem is that the vegetables will need gravity to grow their roots. The thing is that the solution for this kind of problems might be that the joint of the part of the structure of the space station would be equipped with bearings, which allows it to rotate separately. This kind of structures, where the part of the space station would equip with artificial gravity makes possible to operate it in the long-term spaceflight, and at the same time make microgravity tests.
If we are thinking about technology, the nanocomposite materials would give one response to the special materials, what could fix themselves. There are two ways to make those materials. One version is to make them with molecules, what structure forms the miniaturized saw shape structure. If there would be damage to that layer, the opposite poles of electricity could just pull the structure back together. This kind of version would make possible to fix small holes on the outer layer, what will be caused by micrometeorites.
But the other version of advanced materials would be even more futuristic. It is a combination of living structures and special latex or carbon fiber, which will make a very hard structure. The idea of this structure is benefiting the catenative cells, which are covered with cilium.
The revolution in this kind hypothetical materials is that those cells, what might be genetically engineered mushrooms would put in the mass of the carbon fiber, and the cilium would start to transfer the carbon fiber or special polymer in the structure. The thing is that if we would think that the cells would make chains between each other, that thing would make possible to control the direction, where those cells are growing.
The nano-size robot could pull the lead cell in some direction, or those cells would be equipped with iron bites. That allows the system to pull those cells to a certain direction, and then the special polymer will cover that layer. Those cells can make even big layer, and then the polymer will make that structure hard. So, this might be the material of tomorrow, which might revolutionize the design of special materials.
Long-term space explorations are fascinating topics for writing, and they are giving endless material for philosophers, engineers, and people, who are just enjoying imagine those kinds of things, what might revolutionize our point of view things in someday. The nutrient is the most important thing in manned space explorations, and that is a vital role in the manned space projects, and the idea is to grow vegetables in the spacecraft.
This kind of ideas where the nutrient can grow in the spacecraft or space station would make the space stations cheaper to maintain. The problem is that the space stations could be used in microgravity tests, and the thing is that if we would try to create artificial gravity in the space stations, what are looking like ISS (International Space Station) might break the structure, and also deny to use microgravity.
But the problem is that the vegetables will need gravity to grow their roots. The thing is that the solution for this kind of problems might be that the joint of the part of the structure of the space station would be equipped with bearings, which allows it to rotate separately. This kind of structures, where the part of the space station would equip with artificial gravity makes possible to operate it in the long-term spaceflight, and at the same time make microgravity tests.
If we are thinking about technology, the nanocomposite materials would give one response to the special materials, what could fix themselves. There are two ways to make those materials. One version is to make them with molecules, what structure forms the miniaturized saw shape structure. If there would be damage to that layer, the opposite poles of electricity could just pull the structure back together. This kind of version would make possible to fix small holes on the outer layer, what will be caused by micrometeorites.
But the other version of advanced materials would be even more futuristic. It is a combination of living structures and special latex or carbon fiber, which will make a very hard structure. The idea of this structure is benefiting the catenative cells, which are covered with cilium.
The revolution in this kind hypothetical materials is that those cells, what might be genetically engineered mushrooms would put in the mass of the carbon fiber, and the cilium would start to transfer the carbon fiber or special polymer in the structure. The thing is that if we would think that the cells would make chains between each other, that thing would make possible to control the direction, where those cells are growing.
The nano-size robot could pull the lead cell in some direction, or those cells would be equipped with iron bites. That allows the system to pull those cells to a certain direction, and then the special polymer will cover that layer. Those cells can make even big layer, and then the polymer will make that structure hard. So, this might be the material of tomorrow, which might revolutionize the design of special materials.
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